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Semi-physiologically based pharmacokinetic
modeling of paclitaxel metabolism and in silicobased study of the dynamic sensitivities in
pathway kinetics
Martin N Fransson, Jan Brugard, Peter Aronsson and Henrik Green
Linköping University Post Print
N.B.: When citing this work, cite the original article.
riginal Publication:
Martin N Fransson, Jan Brugard, Peter Aronsson and Henrik Green, Semi-physiologically
based pharmacokinetic modeling of paclitaxel metabolism and in silico-based study of the
dynamic sensitivities in pathway kinetics, 2012, European Journal of Pharmaceutical
Sciences, (47), 4, 759-767.
http://dx.doi.org/10.1016/j.ejps.2012.08.002
Copyright: Elsevier
http://www.elsevier.com/
Postprint available at: Linköping University Electronic Press
http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-86649
Semi-physiologically based pharmacokinetic modeling of
paclitaxel metabolism and in silico-based study of the
dynamic sensitivities in pathway kinetics
Martin N. Franssona,∗, Jan Brugårdb , Peter Aronssonb , Henrik Gréenc,d
a
Department of Medical Epidemiology and Biostatistics, Karolinska Institutet,
Stockholm, Sweden
b
MathCore Engineering AB, Linköping, Sweden
c
Division of Drug Research, Department of Medical and Health Sciences, Linköping
University, Linköping, Sweden
d
Science for Life Laboratory, School of Biotechnology, Division of Gene Technology,
KTH Royal Institute of Technology, Solna, Sweden
Abstract
Purpose: To build a semi-physiologically based pharmacokinetic model describing the uptake, metabolism and efflux of paclitaxel and its metabolites
and investigate the effect of hypothetical genetic polymorphisms causing reduced uptake, metabolism or efflux in the pathway by model simulation and
sensitivity analysis.
Methods: A previously described intracellular pharmacokinetic model was
used as a starting point for model development. Kinetics for metabolism,
transport, binding and systemic and output compartments were added to
mimic a physiological model with hepatic elimination. Model parameters
were calibrated using constraints postulated as ratios of concentrations and
amounts of metabolites and drug in the systemic plasma and output compartments. The sensitivity in kinetic parameters was tested using dynamic
sensitivity analysis.
Results: Predicted plasma concentrations of drug and metabolites were in the
range of what has been observed in clinical studies. Given the final model,
∗
Corresponding author. Present address: Department of Medical Epidemiology and
Biostatistics, Karolinska Institutet, PO Box 281, SE-171 77, Stockholm, Sweden. Tel.:
+46 8 524 839 74; fax: +46 8 31 49 75.
Email address: [email protected] (Martin N. Fransson)
June 27, 2012
plasma concentrations of paclitaxel seems to be relatively little affected by
changes in metabolism or transport, while its main metabolite may be largely
affected even by small changes. If metabolites prove to be clinically relevant,
genetic polymorphisms may play an important role for individualizing paclitaxel treatment.
Keywords: Paclitaxel metabolism, Mathematical modeling,
Pharmacokinetics, Sensitivity analysis, CYP2C8, CYP3A4, OATP, ABCB1
1. Introduction
Typically, parametric pharmacokinetic modeling starts with fitting oneor several compartments to observed drug concentrations in plasma from repeated sampling from one or several individuals. The latter case is subject to
so called population pharmacokinetics, where the use of nonlinear mixed effects models allow variability in the population to be tested against potential
covariates, such as body-mass, gender or genetic polymorphisms. Finding
significant covariates is especially important for chemotherapeutic drugs because of their potency and narrow therapeutic index (Undevia et al., 2005).
In the case of paclitaxel, a mitotic inhibitor used in treatment for a range
of different tumors, the use of population pharmacokinetic models has indicated sex, age, body weight and bilirubin to be significant covariates (Henningsson et al., 2003; Joerger et al., 2006). However, these covariates explain
only a smaller part of the population variability, and it is believed that pharmacogenetics could play an important role in further reducing variability
(Sparreboom and Figg, 2006). For paclitaxel, potential genetic polymorphisms affecting pharmacokinetics may be associated with the organic aniontransporting polypeptide (OATP) at cellular uptake (Smith et al., 2005), cytochromes P450 2C8 and 3A4/5 (CYP2C8, CYP3A4/5) (Monsarrat et al.,
1993; Cresteil et al., 1994; Harris et al., 1994b; Rahman et al., 1994) during hepatic metabolism or the transporter protein ABCB1 at cellular efflux
(Jang et al., 2001). Two large studies have so far been investigating genetic polymorphisms in association to paclitaxel pharmacokinetics, using the
population pharmacokinetic approach (Henningsson et al., 2005a; Bergmann
et al., 2011). While Henningsson et al. (2005a) found no associations for
polymorphisms in CYP2C8, CYP3A4/5 or ABCB1, Bergmann et al. (2011)
reported the allele CYP2C8*3 to cause an 11% decrease in paclitaxel clearance. The same study also found evidence that the CYP2C8*4 and ABCC1
2
may have an effect on clearance, but found no significant influence of genetic variants in OATP, CYP3A4/5 or ABCB1. In contrast, a few minor
studies have reported ABCB1 polymorphisms to affect either the kinetics
of paclitaxel (Yamaguchi et al., 2006; Green et al., 2009) or of its hydroxy
metabolites (Nakajima et al., 2005; Fransson et al., 2011).
In addition to the top-down pharmacokinetic modeling approach, where
the study data may be a limiting factor for model complexity (Aarons, 2005),
a complementary mechanistic approach may help to understand the relative
importance of the targeted genes, and consequently what findings that may
be expected from a clinical study. For this reason, the aim of the present work
was to develop a semi-physiologically based pharmacokinetic model with detailed description of the uptake, metabolism and efflux of paclitaxel and
its metabolites, by extending an existing in vitro derived intracellular pharmacokinetic model and integration of existing population pharmacokinetic
models. The hypothetical effect of genetic polymorphisms causing reduced
uptake, metabolism or efflux in the pathway was then investigated by the
use of simulation-based dynamic sensitivity analysis.
2. Material and methods
2.1. Model development
A semi-physiologically based pharmacokinetic model was developed using
the software MathModelica ver. 2.1 (MathCore Engineering AB, Linköping,
Sweden), and combined low- and high-level pharmacokinetic models. An
intracellular pharmacokinetic model used to assess the uptake and efflux of
paclitaxel in tumor cells by Kuh et al. (2000) and Jang et al. (2001), was used
as a starting point for model development. Pharmacodynamic effects on the
number of cells were omitted. Kinetic parameters depending on cell number
were up-scaled to represent a female liver of 1475 g (de la Grandmaison
et al., 2001) with a hepatocellularity of 9.9 x 107 cells/g (Barter et al., 2007)
resulting in a cell number of 1.5 x 1011 . The original model, comprising one
compartment each for cells, considered here to be liver tissue, equation (3e),
and cell medium, considered to be liver plasma, (3c), was then extended with
a reservoir or systemic plasma compartment, (3a), and output compartment,
(3g), to conceptually mimic a physiological model for hepatic elimination
(Sirianni and Pang, 1997). A saturable transport mechanism, representing
hepatic uptake facilitated by OATP (Smith et al., 2005), was introduced
3
between the liver plasma compartment, (3c), and liver tissue compartment,
(3e).
In hepatocytes, paclitaxel is mainly metabolized by CYP2C8 to 6αhydroxypaclitaxel (Harris et al., 1994a; Kumar et al., 1994; Rahman et al.,
1994), or by CYP3A4 to p-3’-hydroxypaclitaxel (Harris et al., 1994b). Both
hydroxy metabolites can be further metabolized to 6α-, p-3’-dihydroxypaclitaxel,
by CYP3A4 or CYP2C8 (Sonnichsen et al., 1995). Hence, two metabolizing
mechanisms, representing CYP2C8 and CYP3A4, were added in the liver
tissue compartment, (3e), using Michaelis-Menten kinetics.
Because of its lipophilic properties, paclitaxel is usually administrated as
an infusion, dissolved in the formulation vehicle Cremophor EL, which has
been shown to affect the kinetics of the drug (Sparreboom et al., 1996), and
most likely the kinetics of the two primary hydroxy metabolites (Fransson
et al., 2011). Binding of drug to Cremophor EL and proteins in the systemic
and liver plasma compartments, (3a) and (3c), was assumed to be instantaneous by including an equation derived from population pharmacokinetic
modeling by Henningsson et al. (2001), describing the relation between total
and unbound concentrations, (3b) and (3d). Cremophor EL concentrations
were simulated using a previously reported three-compartment model (Henningsson et al., 2005b), also in the Appendix, equation A.5.
For each physiological compartment, four ordinary differential equations
had to be used, each one representing the drug or one of the three metabolites.
In total, the model consisted of a system of 19 ordinary differential equations,
where the corresponding time-dependent variables are presented in Table 1.
Initial estimates for physiological and kinetic parameters for paclitaxel were
derived from various literature sources according to Table A.4. Because little
kinetic data is available about paclitaxel metabolites, it was assumed that all
binding parameters for metabolites are the same as for paclitaxel, with the
exception of binding to Cremophor EL (Fransson et al., 2011). Initial values
(pre-optimization) for enzyme kinetics of metabolites were also taken to be
the same as the corresponding ones for the parent drug.
2.2. Constrained optimization
To mimic the in vivo situation as far as possible the semi-physiologically
based model was subject to constrained optimization. Two time-points were
chosen to constrain the model in such a way that the simulations would give
reasonable ratios between metabolite and parent drug concentrations and
amounts. To describe the relation between total concentrations of parent
4
Table 1: Time-dependent variables
Variable
x1 (t)
x2 (t)
x3 (t)
x4 (t)
x5 (t)
x6 (t)
x7 (t)
x8 (t)
x9 (t)
x10 (t)
x11 (t)
x12 (t)
x13 (t)
x14 (t)
x15 (t)
x16 (t)
x17 (t)
x18 (t)
x19 (t)
Meaning
Total conc. (µM) paclitaxel in systemic plasma
Total conc. (µM) paclitaxel in liver plasma
Total conc. (µM) paclitaxel in liver tissue
Total conc. (µM) 6α-hydroxypaclitaxel in systemic plasma
Total conc. (µM) 6α-hydroxypaclitaxel in liver plasma
Total conc. (µM) 6α-hydroxypaclitaxel in liver tissue
Total conc. (µM) p-3’-hydroxypaclitaxel in systemic plasma
Total conc. (µM) p-3’-hydroxypaclitaxel in liver plasma
Total conc. (µM) p-3’-hydroxypaclitaxel in liver tissue
Total conc. (µM) 6α-, p-3’-dihydroxypaclitaxel in systemic plasma
Total conc. (µM) 6α-, p-3’-dihydroxypaclitaxel in liver plasma
Total conc. (µM) 6α-, p-3’-dihydroxypaclitaxel in liver tissue
Amount (µmol) paclitaxel in output compartment
Amount (µmol) 6α-hydroxypaclitaxel in output compartment
Amount (µmol) p-3’-hydroxypaclitaxel in output compartment
Amount (µmol) 6α-, p-3’-dihydroxypaclitaxel in output compartment
Conc. (ml/l) Cremophor EL in central compartment
Conc. (ml/l) Cremophor EL in first peripheral compartment
Conc. (ml/l) Cremophor EL in second peripheral compartment
drug and metabolites in systemic plasma, an earlier developed model was simulated (Fransson et al., 2011), and the total concentrations of the population
means at time (t) at three hours, end of infusion, was noted. Total paclitaxel
concentration (x1 (t)) was taken as the reference level, and total concentrations of 6α-hydroxypaclitaxel (x4 (t)), p-3’-hydroxypaclitaxel (x7 (t)) and 6α-,
p-3’-dihydroxypaclitaxel (x10 (t)) was used to determine an appropriate ratio for total concentrations. Ratios of the amounts of 6α-hydroxypaclitaxel
(x14 (t)), p-3’-hydroxypaclitaxel (x15 (t)) and 6α-, p-3’-dihydroxypaclitaxel
(x16 (t)) to parent drug (x13 (t)) in output were estimated using information
about the mean extractable radioactivity from fecal collections as reported by
Walle et al. (1995). Only the parent drug and three mentioned metabolites
were considered, and the ratios were calculated from the sum of these four
compounds. The constraint in the output compartment was set to t = 18
hours, a compromise between amounts being stable (flattened curves) and
5
computation time. Moreover, all the constraints were somewhat relaxed
by allowing a 20% deviation from the reference level. The constraints are
summarized in Table 2. Initial values for the model are presented in the ApTable 2: Optimization constraints in systemic plasma and output
compartment
Variable
x4 (t)
x7 (t)
x10 (t)
x14 (t)
x15 (t)
x16 (t)
Reference level
0.066x1 (t = 3)
0.018x1 (t = 3)
0.018x1 (t = 3)
5.2x13 (t = 18)
0.38x13 (t = 18)
1.2x13 (t = 18)
Constraint with 20% deviation
0.053x1 (3) < x4 (3) < 0.079x1 (3)
0.014x1 (3) < x7 (3) < 0.022x1 (3)
0.014x1 (3) < x10 (3) < 0.022x1 (3)
4.1x13 (18) < x14 (18) < 6.2x13 (18)
0.30x13 (18) < x15 (18) < 0.46x13 (18)
0.94x13 (18) < x16 (18) < 1.4x13 (18)
pendix in Table A.4 and Table A.5. A manual optimization step using the
MathModelica Simulation Center was first carried out to put the constrained
variables approximately within a 50% deviation from the reference level. In
this step, only Vmax parameters where adjusted. Constrained optimization
was then carried out in Mathematica ver. 8 (Wolfram Research, Inc., Champaign, IL, USA) using the NDSolve and FindMinimum routines, with several
subsequent steps until all constraints were fulfilled with 20% maximum deviation from the reference level. In this second step, all Vmax and related KM
parameters, as well as the parameters describing binding to Cremophor EL,
BCrEL , were subject to the optimization procedure.
2.3. Dynamic sensitivity analysis
Dynamic sensitivity analysis was performed in MathModelica Simulation
Center using the CVODES solver, which supports forward sensitivity analysis
(Hindmarsh et al., 2005). The sensitivity si for a parameter p is calculated
as
∂xi
(1)
si,p =
∂p
where xi is the ith (state) variable. The forward sensitivity analysis will
provide the local sensitivity for the parameters under consideration (Varma
et al., 1999; Wu et al., 2008). This means that the results from the analysis
are conditional on the specific parameter estimates, and that the sensitivity
may not be valid for another set of estimates.
6
Sensitivity was tested on all Vmax and related Km parameters by first
introducing a parameter, GE (”genetic effect”). This parameter effects either
the Vmax or the Km independently of the substrate. For instance
pac
pac
Vmax
Vmax
VmaxOAT
P → GE OAT P · VmaxOAT P , GE OAT P = 1
(2)
max
so that the sensitivity in the parameter GE VOAT
P can be tested. This way, the
sensitivity will be independent of the magnitude of the different Vmax , and
the effect of reduced capacity in transporters and enzymes can be compared.
3. Results
3.1. Model development and constrained optimization
The final model for paclitaxel is described by equations (3a)-(3g), where
the differential equations (3a), (3c) and (3e) represent the kinetics for total
concentrations of paclitaxel, x1 -x3 , and equations (3b), (3d) and (3f) represent the relation between total, x1 -x3 , and unbound concentrations, y1 -y3 .
Equation (3g) represents the change in amount of drug, x13 , in the output
compartment. The descriptions of each variable can be found in Table 1.
The full model including kinetics for metabolites is represented by Figure 1,
and all the underlying equations can be found in Appendix A.
VSysP l · ẋ1 = −QLivP l (x1 − x2 ) + Dosepac
BmaxP l · y1
KmP l + y1
pac
VmaxOAT
P · y2
= QLivP l (x1 − x2 ) − QLivT i (y2 − y3 ) − pac
KmOAT P + y2
BmaxP l · y2
pac
= y2 + (BlinP l + BCrEL
· x17 ) · y2 +
KmP l + y2
pac
V
P · y2
= QLivT i (y2 − y3 ) + maxOAT
pac
KmOAT P + y2
pac
pac
pac
Vmax2C8 · y3 Vmax3A4 · y3 VmaxABC
· y3
− pac
− pac
− pac
Km2C8 + y3 Km3A4 + y3 KmABC + y3
BmaxT i · y3
= y3 + BlinT i · y3 +
KmT i + y3
pac
V
· y3
= maxABC
pac
KmABC + y3
pac
x1 = y1 + (BlinP l + BCrEL
· x17 ) · y1 +
VLivP l · ẋ2
x2
VLivT i · ẋ3
x3
ẋ13
7
(3a)
(3b)
(3c)
(3d)
(3e)
(3f)
(3g)
y4 x1 y7 x4 Systemic plasma y1 x18 y10 x7 x10 QLivPl x17 x5 y2 x19 QLivTi OATP x8 x11 y5 QLivTi y8 QLivTi OATP OATP y11 QLivTi OATP CYP2C8 y6 CYP3A4 y3 x9 CYP3A4 y12 y9 Liver Cssue x6 x3 Liver plasma x2 x12 CYP2C8 ABCB1 ABCB1 ABCB1 x13 x14 x15 x16 Output ABCB1 Figure 1: The final model structure. x1 -x19 , time-dependent variables
according to Table 1 and y1 -y12 , the corresponding unbound concentrations.
Black dashed arrows represent binding, black solid arrows represent enzyme
kinetics and double-edged gray arrows represent compartmental flows.
8
The parameter estimates from the constrained optimization is presented
in Appendix A, Table A.5. The concentration of total paclitaxel and metabolites in the systemic plasma, liver plasma, liver tissue compartments, as well
as the amount in the output compartment from a 20 hour simulation of the
final model with a three-hour infusion is shown in Figure 2.
The final step during the optimization consisted of taking the estimates
from a 30% to a 20% maximum deviation. Using the Mathematica Timing
function, the last step was measured to approximately 6.1 hours of computational time on a Lenovo T61 with Intel Core Duo CPU 2.00 GHz and 1.96
GB RAM, using Windows XP.
3.2. Dynamic sensitivity analysis
Dynamic sensitivities for GE Km parameters behaved similar but in the
opposite direction of those for the corresponding GE Vmax parameters. The
later ones are shown in Figure 3 for the systemic plasma compartment and
in Figure 4 for the output compartment. A negative sensitivity means a decrease in GE Vmax will result in an increased plasma concentration or amount.
The effect on a concentration or amount of a change in a particular GE Vmax
can be estimated by approximating (1). For instance, a 10% decrease in
max
GE VOAT
max = −1.2 at t = 3 hours (Figure 3, top left), will inP with s1,GE V
OAT P
crease the total paclitaxel concentration in systemic plasma from x̂1 (3) = 5.25
µM (Figure 2, top left) to approximately
max
x̂1 (3) + s1,GE Vmax (3) · ∂GE VOAT
P ≈ 5.25 + (−1.2) · (−0.10) = 5.37 µM (4)
OAT P
Given the final model estimates, systemic plasma concentration of paclitaxel
max
was clearly most sensitive to changes in GE VOAT
P , describing the uptake by
OATP, were a change will have more than 10 times the effect compared to a
change in the metabolism by CYP2C8 at t = 3 hours, which had the second
most sensitive GE Vmax (Figure 3, top left). For 6α-hydroxypaclitaxel, the
ABCB1 transporter is most sensitive, with increasing plasma concentrations
max
for decreasing GE VABC
, and with CYP2C8 as being second most sensitive,
max
with decreasing plasma concentrations for decreasing GE V2C8
(Figure 3, top
right).
In the output compartment, the amount of paclitaxel was most sensitive
max
to changes in ABCB1, where a decreasing GE VABC
will give rise to a decreasing amount (Figure 4, top left). For the amount of 6α-hydroxypaclitaxel,
metabolism by CYP2C8 is most sensitive, although an equal change in
9
1E+01
Total concentration in liver plasma [microM]
Total concentration in systemic plasma [microM]
1E+01
1E+00
1E-01
1E-02
1E-03
1E-01
1E-02
1E-03
0
5
10
Time [h]
15
20
0
5
10
Time [h]
15
20
250
Amount in output compartment [micromol]
1E+02
Total concentration in liver tissue [microM]
1E+00
1E+01
1E+00
1E-01
1E-02
1E-03
200
150
100
50
0
0
5
10
Time [h]
15
20
0
5
10
Time [h]
15
Figure 2: Simulations from the final model of total concentrations in
systemic plasma (top left), liver plasma (top right), liver tissue (bottom
left) and amounts in output compartment (bottom right) of paclitaxel
(solid), 6α-hydroxypaclitaxel (dashed), p-3’-hydroxypaclitaxel (dotted) and
6α-, p-3’-dihydroxypaclitaxel (dash-dotted).
10
20
metabolism by CYP3A4 will have an almost as big but opposite effect (Figure 4, top right). For all compounds in the output compartment, effects from
changed uptake by the OATP transporter are small in comparison to changes
in metabolism or efflux.
A summary of the effect on paclitaxel and 6α-hydroxypaclitaxel of a 10%
decrease in GE Vmax can be found in Table 3.
Table 3: Change in concentration and amount from a 10% decrease in
different GE Vmax
Vmax
Vmax
Vmax
max
Variablea GE VOAT
P = 0.9 GE 2C8 = 0.9 GE 3A4 = 0.9 GE ABC = 0.9
x1 (3)
2.3%
0.2%
0.1%
0.0%
x4 (3)
5.0%
-9.4%
6.7%
34.0%
x13 (18)
0.0%
4.1%
1.4%
-9.0%
x14 (18)
0.0%
-3.2%
2.3%
1.6%
a
x1 (3): total paclitaxel concentration in systemic plasma at three hours;
x4 (3): total 6α-hydroxypaclitaxel concentration in systemic plasma at 3
hours; x13 (18): amount paclitaxel in output compartment at 18 hours;
x14 (18): amount 6α-hydroxypaclitaxel in output compartment at 18 hours
4. Discussion
The simulated Cmax of 5.25 µM for total concentration of paclitaxel at
t = 3 hours in Figure 1 is in the same range as the observed Cmax from
three-hour infusions reported previously by Walle et al. (1995), with 6-10
µM; Karlsson et al. (1999), 2-10 µM; Henningsson et al. (2001), 1-10 µM;
Joerger et al. (2006), 1-4 µM. Because of the three-hour constraints in the
systemic compartment, maximum total concentrations of metabolites are also
in the right range (Czejka et al., 2003; Fransson et al., 2011). The flat phase
following the initial rapid increase in concentration and preceding the end of
infusion at three hours is not evident from clinical data (Walle et al., 1995;
Karlsson et al., 1999; Czejka et al., 2003; Joerger et al., 2006), which could be
a consequence of the limited compartmental space in systemic plasma with increased binding as result. Simulation using a ten times larger volume for systemic plasma removed the two distinct phases (data not shown). Previously
described population pharmacokinetic models have used two (Henningsson
et al., 2001, 2005a; Joerger et al., 2006) or at least one (Henningsson et al.,
11
Vmax sensitivity for 6-alpha-hydroxypaclitaxel in systemic plasma
Vmax sensitivity for paclitaxel in systemic plasma
0.0
-0.2
-0.4
-0.6
-0.8
-1.0
-1.2
-1.4
5
10
Time [h]
15
0.04
0.02
0.00
-0.02
-0.04
-0.06
-0.08
-0.10
0
5
10
Time [h]
15
0.2
0.0
-0.2
-0.4
-0.6
-0.8
-1.0
-1.2
-1.4
20
0
Vmax sensitivity for 6-alpha-p-3'-dihydroxypaclitaxel in systemic
plasma
Vmax sensitivity for p-3'-hydroxypaclitaxel in systemic plasma
0
0.4
20
5
10
Time [h]
15
0.15
0.10
0.05
0.00
-0.05
-0.10
-0.15
-0.20
-0.25
0
5
10
Time [h]
15
Figure 3: Sensitivity in GE Vmax for OATP (solid), CYP2C8 (dashed),
CYP3A4 (dotted) and ABCB1 (dash-dotted) in systemic plasma
concentrations of paclitaxel (top left), 6α-hydroxypaclitaxel (top right),
p-3’-hydroxypaclitaxel (bottom left) and 6α-, p-3’-dihydroxypaclitaxel
(bottom right).
12
20
20
80
Vmax sensitivity for 6-alpha-hydroxypaclitaxel in output
compartment
Vmax sensitivity for paclitaxel in output compartment
50
40
30
20
10
0
-10
-20
-30
40
20
0
-20
-40
-60
0
5
10
Time [h]
15
20
15
Vmax sensitivity for 6-alpha-p-3'-dihydroxypaclitaxel in output
compartment
Vmax sensitivity for p-3'-hydroxypaclitaxel in output compartment
60
10
5
0
-5
-10
-15
-20
0
5
10
Time [h]
15
20
0
5
10
Time [h]
15
20
0
5
10
Time [h]
15
20
60
40
20
0
-20
-40
Figure 4: Sensitivity in GE Vmax for OATP (solid), CYP2C8 (dashed),
CYP3A4 (dotted) and ABCB1 (dash-dotted) in output amounts of
paclitaxel (top left), 6α-hydroxypaclitaxel (top right),
p-3’-hydroxypaclitaxel (bottom left) and 6α-, p-3’-dihydroxypaclitaxel
(bottom right).
13
2003; Bergmann et al., 2011) additional peripheral compartments, although
in some cases, for total concentrations of paclitaxel, additional compartments
may have been attributable to Cremophor EL binding (Karlsson et al., 1999;
Joerger et al., 2006). The lack of peripheral compartments in the present
model is also evident from the rapid decrease in total concentrations after
the 3 hour infusion. Addition of peripheral compartments to the model were
considered, but because previous models are either based on unbound concentrations (Henningsson et al., 2001, 2003, 2005a; Bergmann et al., 2011) or
does not explicitly handle binding to Cremophor EL (Karlsson et al., 1999;
Joerger et al., 2006), such an approach would mean even more assumptions
would need to be accounted for. There are also few sources with parametric models describing the kinetics of paclitaxel metabolites (Fransson et al.,
2011).
As a result of the rapid elimination of paclitaxel and metabolites from systemic plasma, amounts in the output compartment are likely to increase and
stabilize more rapidly in the present model than in vivo. From Figure 2 (bottom right) it is evident that amounts in the output compartment are stable
from approximately 8 hours, which would mean that selecting t = 18 hours
for the constraint on metabolite-drug ratios is sufficient, although the constraint is derived from information on fecal collections between 24-48 hours
(Walle et al., 1995). The efflux from liver tissue to the output compartment
is fully dependent on the ABCB1 transporter, and no diffusion is assumed
with the possibility of a back-flow. A mathematical model by Bartholome
et al. (2007) describing vectorial transport by OATP1B3 and ABCC2 across
polarized cells found an additional leakage component for efflux over the apical membrane. For the present model, this may indicate that the importance
of the transporter ABCB1 will be overestimated for the output compartment. However, because an appropriate volume of the output compartment
is difficult to estimate a concentration cannot be determined, something that
would be required for a diffusion mechanism. Diffusion would also be affected
by the accumulation of the amounts in the output compartment, and this
accumulation would not be representative for the in vivo situation.
The total paclitaxel plasma concentration in the systemic compartment
max
is most sensitive to changes in GE VOAT
P . However, the absolute effect on
the plasma concentration is small. According to Table 3 a 10% decrease in
max
GE VOAT
P will only provide an 2.3% increase in concentration at the end of
infusion at 3 hours. This can be compared to the effect of a 10% decrease in
max
, which will cause total concentrations of 6α-hydroxypaclitaxel to inGE VABC
14
crease with 34% at the same point in time. Given the final model estimates,
total paclitaxel concentrations are relatively little affected by changes in GE
parameters. If the model and final estimates are to be considered representative for the in vivo situation, it would mean that neither of the investigated
transporters, nor the metabolizing enzymes, play a major role in the population variability of paclitaxel plasma concentrations. Hence, they would not
show up as significant covariates in clinical studies using population pharmacokinetic data. This may explain the absence of findings by Henningsson
et al. (2005a), and the relatively modest effect on decreased clearance by
Bergmann et al. (2011). In the same way, the predicted relatively large effect on 6α-hydroxypaclitaxel plasma concentrations from decreased capacity
in the ABCB1 transporter is supported by our previous findings (Fransson
et al., 2011), where individuals carrying the polymorphisms G/A or G/G
(wild-type) showed a 30% increase, and individuals with polymorphism T/T
showed a 27% decrease, relative individuals with polymorphism G/T. The result that genetic variation may influence the metabolite concentrations more
than paclitaxel is in accordance with the hypothesis proposed by Leskela et al.
(2011). They found that CYP2C8*3, CYP2C8 Haplotype C and CYP3A5*3
correlates to paclitaxel-induced neuropathy and suggested that the metabolites are affecting the risk of neuropathy.
Because local sensitivity analysis is used, the sensitivities in Figures 3
and 4 and the effects in Table 3 are only valid for small deviations from the
final parameter estimates (Appendix, Table A.5). The validity of the sensitivity analysis can be tested by manually reducing the parameter estimates
and then perform a new simulation. Such simulations showed that a 10%
decrease in the estimate agree with the local sensitivity analysis, but that
a 50% decrease in some cases are too big, and that the sensitivity plots in
Figures 3 and 4 cannot be used to accurately predict such a large deviation
(data not shown). This should be considered if effects from genetic polymorphisms are considered to be large, in which case the solution would be an
additional simulation using a reduced estimate.
In conclusion, the developed model predicts plasma concentrations of
drug and metabolites that are in the range of observations from clinical studies. Given the final model structure with parameter estimates derived from
constrained optimization, while plasma concentrations of paclitaxel seems
to be relatively little affected by changes in the capacity of transport or
metabolism, its main metabolite 6α-hydroxypaclitaxel may be largely affected even by small changes. If future studies can confirm that paclitaxel
15
metabolites are clinically relevant, the present work indicates that genetic
polymorphisms may play an important role for individualizing paclitaxel
treatment.
Acknowledgements
This work has been supported by the Swedish Knowledge Foundation
through the Industrial PhD programme in Medical Bioinformatics at the
Strategy and Development Office (SDO) at Karolinska Institutet, the Swedish
Cancer Society and the Swedish Research Council.
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20
Appendix A. Model equations and parameter estimates
VSysP l · ẋ1 = −QLivP l (x1 − x2 ) + Dosepac
BmaxP l · y1
KmP l + y1
V pac
P · y2
= QLivP l (x1 − x2 ) − QLivT i (y2 − y3 ) − maxOAT
pac
KmOAT P + y2
BmaxP l · y2
pac
= y2 + (BlinP l + BCrEL
· x17 ) · y2 +
KmP l + y2
pac
V
P · y2
= QLivT i (y2 − y3 ) + maxOAT
pac
KmOAT P + y2
pac
pac
pac
V
· y3 Vmax3A4 · y3 VmaxABC
· y3
−
−
− max2C8
pac
pac
pac
Km2C8 + y3 Km3A4 + y3 KmABC + y3
BmaxT i · y3
= y3 + BlinT i · y3 +
KmT i + y3
pac
V
· y3
= maxABC
pac
KmABC + y3
pac
x1 = y1 + (BlinP l + BCrEL
· x17 ) · y1 +
VLivP l · ẋ2
x2
VLivT i · ẋ3
x3
ẋ13
VSysP l · ẋ4 = −QLivP l (x4 − x5 )
x5
VLivT i · ẋ6
x6
ẋ14
(A.1b)
(A.1c)
(A.1d)
(A.1e)
(A.1f)
(A.1g)
(A.2a)
BmaxP l · y4
KmP l + y4
6α
VmaxOAT
P · y5
= QLivP l (x4 − x5 ) − QLivT i (y5 − y6 ) − 6α
KmOAT P + y5
B
maxP l · y5
6α
= y5 + (BlinP l + BCrEL
· x17 ) · y5 +
KmP l + y5
6α
VmaxOAT
·
y
5
P
= QLivT i (y5 − y6 ) + 6α
KmOAT P + y5
pac
6α
6α
V
· y3 Vmax3A4 · y6 VmaxABC
· y6
+ max2C8
− 6α
− 6α
pac
Km2C8 + y3 Km3A4 + y6 KmABC + y6
BmaxT i · y6
= y6 + BlinT i · y6 +
KmT i + y6
6α
V
· y6
= maxABC
6α
KmABC + y6
6α
x4 = y4 + (BlinP l + BCrEL
· x17 ) · y4 +
VLivP l · ẋ5
(A.1a)
21
(A.2b)
(A.2c)
(A.2d)
(A.2e)
(A.2f)
(A.2g)
VSysP l · ẋ7 = −QLivP l (x7 − x8 )
(A.3a)
0
p−3
x7 = y7 + (BlinP l + BCrEL
· x17 ) · y7 +
BmaxP l · y7
KmP l + y7
(A.3b)
0
VLivP l · ẋ8 = QLivP l (x7 − x8 ) − QLivT i (y8 − y9 ) −
p−3
VmaxOAT
P · y8
0
p−3
KmOAT
P + y8
BmaxP l · y8
p−30
x8 = y8 + (BlinP l + BCrEL
· x17 ) · y8 +
KmP l + y8
(A.3c)
(A.3d)
0
VLivT i · ẋ9 = QLivT i (y8 − y9 ) +
p−3
VmaxOAT
P · y8
0
p−3
KmOAT
P + y8
0
0
pac
p−3
p−3
Vmax3A4
· y3 Vmax2C8
· y9
· y9 VmaxABC
+ pac
− p−30
− p−30
Km3A4 + y3 Km2C8 + y9 KmABC + y9
BmaxT i · y9
x9 = y9 + BlinT i · y9 +
KmT i + y9
(A.3e)
(A.3f)
0
ẋ15 =
p−3
VmaxABC
· y9
(A.3g)
0
p−3
KmABC
+ y9
22
VSysP l · ẋ10 = −QLivP l (x10 − x11 )
(A.4a)
BmaxP l · y10
(A.4b)
KmP l + y10
V di
P · y11
= QLivP l (x10 − x11 ) − QLivT i (y11 − y12 ) − maxOAT
di
KmOAT P + y11
(A.4c)
BmaxP l · y11
di
(A.4d)
= y11 + (BlinP l + BCrEL
· x17 ) · y11 +
KmP l + y11
V di
P · y11
= QLivT i (y11 − y12 ) + maxOAT
di
KmOAT P + y11
di
x10 = y10 + (BlinP l + BCrEL
· x17 ) · y10 +
VLivP l · ẋ11
x11
VLivT i · ẋ12
0
x12
ẋ16
p−3
di
6α
Vmax3A4
· y6 Vmax2C8
· y9 VmaxABC
· y12
+ 6α
+ p−30
− di
Km3A4 + y6 Km2C8 + y9 KmABC + y12
BmaxT i · y12
= y12 + BlinT i · y12 +
KmT i + y12
di
· y12
V
= maxABC
di
KmABC + y12
(A.4e)
(A.4f)
(A.4g)
V1CrEL · ẋ17 = −QCrEL
(x17 − x18 ) − QCrEL
(x17 − x19 )
12
13
CrEL
· x17
Vmax
+ DoseCrEL
CrEL
Km
+ x17
= QCrEL
(x17 − x18 )
12
−
V2CrEL · ẋ18
V3CrEL · ẋ19 = QCrEL
(x17 − x19 )
13
23
(A.5a)
(A.5b)
(A.5c)
24
Parameter
Estimate Meaning
Reference
VSysP l (l)
2.358
Volume systemic plasma
Hurley (1975): S = 1.71 and subtracting VLivP l
a
VLivP l (l)
0.2
Volume liver plasma
Taniguchi et al. (1996); Geraghty et al. (2004)
VLivT i (l)
0.29b
Volume liver tissue
Jang et al. (2001): BC19 volume of 1.96 pl
QLivP l (l/h)
60
Flow VSysP l and VLivP l
Molino et al. (1991)
b
QLivT i (l/h)
543
Flow VLivP l and VLivT i
Jang et al. (2001)
BmaxT i (µM)
61.5
Maximal intracellular binding
Jang et al. (2001)
KmT i (µM)
0.00524
Concentration at half BmaxT i
Jang et al. (2001)
BlinT i
0.118
Linear intracellular binding
Jang et al. (2001)
BmaxP l (µM)
0.0245
Maximal binding in plasma
Henningsson et al. (2001)
KmP l (µM)
0.000106 Concentration at half BmaxP l
Henningsson et al. (2001)
BlinP l
7.59
Linear binding in plasma
Henningsson et al. (2001)
pac
9200b
Maximum uptake rate OATP
Smith et al. (2005)
VmaxOAT
P (µmol/h)
pac
pac
Smith
et al. (2005)
KmOAT P (µM)
6.79
Concentration at half VmaxOAT
P
pac
c
Vmax2C8 (µmol/h)
170
Maximum reaction rate CYP2C8
Cresteil et al. (2002); Naraharisetti et al. (2010)
pac
pac
Km2C8 (µM)
15
Concentration at half Vmax2C8
Cresteil et al. (2002)
pac
Vmax3A4
(µmol/h)
100c
Maximum reaction rate CYP3A4
Cresteil et al. (2002); Kato et al. (2010)
pac
pac
Km3A4
(µM)
15
Concentration at half Vmax3A4
Cresteil et al. (2002)
pac
b
VmaxABC (µmol/h) 41
Maximum efflux rate ABCB1
Jang et al. (2001)
pac
pac
KmABC
(µM)
0.0139
Concentration at half VmaxABC
Jang et al. (2001)
pac
BCrEL
3.78
Binding to CrEL in plasma
Henningsson et al. (2001)
V1CrEL (l)
4.54
Volume central comp. CrEL
Henningsson et al. (2005b)
V2CrEL (l)
1.32
Volume first periph. comp. CrEL
Henningsson et al. (2005b)
CrEL
V3
(l)
3.53
Volume second periph. comp. CrEL Henningsson et al. (2005b)
QCrEL
(l/h)
1.17
Flow between V1CrEL and V2CrEL
Henningsson et al. (2005b)
12
CrEL
CrEL
CrEL
Q13
(l/h)
0.479
Flow between V1
and V3
Henningsson et al. (2005b)
CrEL
Vmax
(ml/h)
0.64
Maximum elimination rate of CrEL Henningsson et al. (2005b)
CrEL
CrEL
Km
(ml/l)
2.57
Concentration at half Vmax
Henningsson et al. (2005b)
a
Calculated from references and by using a hematocrit value of 0.4
b
Using a cell number of 1.5 x 1011 (de la Grandmaison et al., 2001; Barter et al., 2007)
c
Calculated from references and by using 32 mg microsomal protein per gram of liver (Barter et al., 2007)
Table A.4: Literature derived estimates used as initial estimates for optimization
Table A.5: Estimates from constrained optimization for paclitaxel
transport, metabolism and Cremophor EL binding
Parameter
Initiala Manualb Mathematicac
pac
VmaxOAT
9200
2300
2210
P (µmol/h)
pac
KmOAT P (µM)
6.79
fixed
fixed
pac
Vmax2C8
(µmol/h)
170
68000
108000
pac
Km2C8 (µM)
15
fixed
fixed
pac
Vmax3A4
(µmol/h)
100
40000
35800
pac
Km3A4 (µM)
15
fixed
fixed
pac
VmaxABC (µmol/h) 41
fixed
fixed
pac
KmABC
(µM)
0.0139 fixed
fixed
6α
VmaxOAT P (µmol/h) 9200
4600
4030
6α
KmOAT P (µM)
6.79
fixed
5.79
6α
Vmax3A4
(µmol/h)
100
100
114
6α
(µM)
15
fixed
16.3
Km3A4
6α
82
107
VmaxABC (µmol/h) 41
6α
(µM)
0.0139 fixed
0.0130
KmABC
p−30
VmaxOAT P (µmol/h) 9200
18400
14000
p−30
KmOAT P (µM)
6.79
fixed
8.43
p−30
Vmax2C8 (µmol/h)
170
17000
16900
p−30
Km2C8 (µM)
15
fixed
11.0
p−30
VmaxABC (µmol/h) 41
10
10.4
p−30
KmABC (µM)
0.0139 fixed
0.0143
di
18400
15200
VmaxOAT P (µmol/h) 9200
di
(µM)
6.79
fixed
7.37
KmOAT
P
di
VmaxABC
(µmol/h) 41
41
34.8
di
KmABC (µM)
0.0139 fixed
0.0119
pac
BCrEL
3.78
fixed
fixed
6α
BCrEL
3.78
fixed
4.79
p−30
BCrEL
3.78
fixed
2.85
di
BCrEL
3.78
fixed
3.34
a
From Table A.4. Estimates for parameters governing metabolite kinetics
are assumed to be the same as for the parent drug.
b
Using MathModelica Simulation Center by adjusting Vmax parameters to
meet an approximate 50% deviation from the constraints.
c
Final estimates. Using Mathematica with NDSolve and FindMinimum to
meet a maximum of 20% deviation from the constraints.
25